Energy storage and generation system

ABSTRACT

An energy storage and generation system uses a combination of compressed air energy storage systems and fluid energy systems, to store energy producing capability at a time when electricity requirements are low, to release that stored energy producing capability at a time when electricity requirements are high.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is based on U.S. Provisional Patent Application Ser. No. 62/387,805, filed Jan. 5, 2016; U.S. Provisional Patent Application Ser. No. 62/390,026, filed Mar. 16, 2016; and U.S. Provisional Patent Application Ser. No. 62/392,026, filed May 19, 2016; all of these applications being incorporated herein by reference, and filed by the same inventive entity.

This invention relates to an energy storage and generation system and more particularly to an energy storage and generation system, which combines various energy generating mechanisms with a compressed gas energy storage mechanisms, which uses at least one compressed gas and at least one liquid to store energy for release at an appropriate time to enhance energy efficiency.

BACKGROUND OF THE INVENTION

Electrical energy is the life blood of modern society. However, current systems focus upon maximizing the production of electrical energy solely for certain times of peak consumption and fails to efficiently utilize electrical production capacity outside of those times of peak consumption through the use of storage mechanisms. As such, the need becomes apparent for a means of storing electrical energy in those moments outside of times of peak consumption and to then release the stored energy when demand becomes higher, thereby alleviating energy production demand. For an example of this process one may consider powersouth energy cooperative—turning compressed air to electricity CAES 2015 you tube presentation.

Another important aspect of meeting energy demand, is cost. Energy production costs not only include the costs expended in the generation and storage of power, but also the not so apparent ancillary costs of energy generation and storage on the environment.

A number of systems in the prior art are devised to address some of the known environmental problems with energy generation and storage. Some of these systems includes batteries, flow batteries, fuel cells, super capacitors, superconducting magnetic energy storage, compressed air energy storage, flywheel energy storage, hydroelectric energy storage and gravitational potential energy devices. Each of the abovementioned systems have their advantages and disadvantages. However, capacity and efficiency are limiting factors which reduce the practical utility of most of these systems.

The most common electrical production system which addresses known problems in the art of efficiency and environmental costs is the hydroelectric energy storage system. This system stores energy by pumping water from a lower elevation to a higher elevation (reference to FIG. 1) during periods outside of peak energy demand. During periods of peak energy demand, this system releases the potential energy of the stored water at higher elevation through the use of gravity to drive water through turbines and lower elevation resorvoirs,generating power.

Hydroelectric Energy Storage system addresses the problems of energy capacity, energy efficiency, and ancillary environmental costs, but fails to meet the direct, upfront cost efficiency goals of construction. Furthermore, the Hydroelectric Energy Storage system is limited by the need of a large body of water or a large variation in height. Likewise, other energy storage systems face other inefficiencies.

Conferences considering climate change include the United Nations (UN) Climate Change Conference held in Paris, France, from 30 November to 12 December 2015, having, as its objective, the achievement for the first time in over 20 years of UN negotiations, a binding and universal agreement on climate from all nations of the world. Pope Francis concurs in such actions as evidenced by the publication of an encyclical, “Laudato si” which calls for action against climate change with the intention in part to influence the conference. The International Trade Union Conference also follows the goal of the conference to be “zero carbon, zero poverty”. Furthermore quoting from general secretary of that conference “there are no jobs on a dead planet.”

Adverse impact to the environment from energy production is not limited to global warming and pollutions from greenhouse gases and other such pollutants, but also other serious issues such as the risk of exposure and contamination from other sources such as radioactive, chemical and radio frequency sources (Wikipedia—2015 United Nations Climate Change Conference).

Flywheel energy storage can potentially have a high efficiency up to 90%, but maintaining this efficiency over time can be an issue. Moreover, high tech systems with superconducting bearings suffer from flux creep during operation. Accordingly, the need for new energy storage systems that can better store and recover energy still remains.

SUMMARY OF THE INVENTION

Among the many objectives of this invention is the provision of an energy storage and generation system, which stores energy for future use.

A further objective of this invention is the provision of an energy storage and generation system, which produces desired energy when it is required.

Yet a further objective of this invention is the provision of an energy storage and generation system, which efficiently produces desired energy.

A still further objective of this invention is the provision of an energy storage and generation system, which permits recovery of energy.

Also a further objective of this invention is the provision of an energy storage and generation system, which permits recovery of more energy than is used to put the potential into the energy storage and generation system.

These and other objectives of the invention (which other objectives become clear by consideration of the specification, claims and drawings as a whole) are met by providing an energy storage and generation system, which uses a combination of compressed air energy storage systems and fluid energy systems, to store energy producing capability at a time when electricity requirements are low, to release that stored energy producing capability at a time when electricity requirements are high.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts a conventional pumped storage hydroelectricity device 900 of the prior art.

FIG. 2 depicts a simplified compressed air storage system 802 for energy for energy storage system 100.

FIG. 3 depicts a conventional pumped storage hydroelectricity device 900 of the prior art, which uses at least one compressed gas and at least one liquid to store energy for release at an appropriate time to enhance energy efficiency for energy storage system 100.

FIG. 4 depicts a conventional pumped storage hydroelectricity device 900 of the prior art of FIG. 3 using a pumped storage hydroelectric system 400 combined with the compressed air energy storage system 230 to form a first single system 240 that is more efficient than either of the two systems, as open systems in that the output of the pumped storage hydroelectric system 400 and compressed air energy storage system 230 are not used as a feedback to the energy storage and generation system 200.

FIG. 5 a conventional pumped storage hydroelectricity device 900 of FIG. 4 as modified.

FIG. 6 depicts a conventional pumped storage hydroelectricity device 900 of FIG. 4 as modified.

FIG. 7 depicts a conventional pumped storage hydroelectricity device 900 of FIG. 4 as modified.

FIG. 8 depicts an upgraded or improved system as a first closed system 300, wherein output from the system is utilized in a feedback arrangement in order to provide a dramatic improvement in the overall system efficiency for energy storage system 100.

FIG. 9 depicts an upgraded or improved system as a first closed system 300 of FIG. 8 as modified.

FIG. 10 depicts an upgraded or improved system as a first closed system 300 of FIG. 8 as modified.

FIG. 11 depicts an upgraded or improved system as a first closed system 300 of FIG. 8 as modified.

FIG. 12 depicts another embodiment of general description of the first closed system 300 of FIG. 8 as modified.

FIG. 13 depicts a first operating embodiment of the three vessel system 320 of this invention for energy storage system 100.

FIG. 14 depicts a second operating embodiment of the three vessel system 320 of this invention.

FIG. 15 depicts a third operating embodiment of the three vessel system 320 of this invention.

FIG. 16 depicts is a fourth operating embodiment of the three vessel system 320 of this invention.

FIG. 17 depicts a fifth operating embodiment of the three vessel system 320 of this invention.

FIG. 18 depicts a sixth operating embodiment of the three vessel system 320 of this invention.

FIG. 19 depicts is a seventh operating embodiment of the three vessel system 320 of this invention.

FIG. 20 depicts a eighth operating embodiment of the three vessel system 320 of this invention.

FIG. 21 depicts a five vessel system 600 of the invention in closed position 602 for energy storage system 100.

FIG. 22 depicts a five vessel system 600 of the invention in open position 604.

FIG. 23 depicts a multi-liquid system 700 for energy storage system 100 in operation.

FIG. 24 depicts energy storage system 100 of this invention when the gas supply device 108 is electrolytic.

FIG. 25 depicts a three vessel cryogenic system 800 for energy storage system 100, where the gas supply device 108 is a cryogenic cooling system to produce liquified (or in some cases solidified) gases.

FIG. 26 shows the three vessel system 320 with a heat capture function.

Throughout the figures of the drawings, where the same part appears in more than one figure of the drawings, the same number is applied thereto.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Compressed Air Energy Storage Systems are known energy storage systems whereby air is compressed and stored in a chamber at a lower elevation until electricity generation is required (hereinafter referred to as CAES). On demand, the compressed air is heated and expanded in an expansion turbine to generate electricity. By combining systems to work in tandem with CAES, cost reduction goals and environmental impact goals can be met. The enclosed figures and discussion are intended to explain the concept behind energy storage and generation system of this invention.

The number of vessels depends on the electric contemplated as needed. As the electicity required increases, the number of vessels in the system increases proportionally. As the electicity required decreases, the number of vessels in the system decreases proportionally. The vessels store or contain the liquid or compressed gas as required for the functioning of the system.

The present invention includes a system that stores energy and produces electricity by incorporating a combination of compressed gas and liquids (water, oil and the like) in the system. The drawings explain the concept behind energy storage and generations systems. The application of the system is not limited to these drawings alone. The following are some other variants:

-   -   combination of the system with other energy storage systems;     -   combination with a variant of itself to facilitate operation in         the compression and generation mode simultaneously for         continuous running operation;     -   combination with systems designed to capture heat generated         during compression and use the heat recovered to heat the air         during expansion; and     -   modification of the system to handle high pressures of fluids         and other exceptional parameters.

These are the descriptions of the various elements or devices contained in the drawings:

the external electrical power source 102;

-   -   the electrical integrating device 104;     -   the receiving vessel 106, which can be as simple as an air         receiver in the case where compressed air is used;     -   the gas supply device 108, which is preferably reversible and         can be, but is not limited to, air compressor, cryogenic cooling         systems or electrolytic systems or any other devices or systems         used to produce compressed gas or cryogenic fluids or solids;     -   vessels 110, 112, 114, 194,196, 253, 256, which are used to         contain the working fluids for energy storage and generation         system 100, and which can be as simple as pressure vessels,         reservoirs, underground caverns or anything else that fulfills         their purpose as described in the system operations;     -   electrical switches 116, 118, and 120 which can be         electronically controlled;     -   valves 122, 124, 126, 128, 130, 132, 134, 136, 138, 140, 142,         144, 146, 148, 150, 152, 154, 188, 198, 200, 202, 204, 206, 208,         222, 232, 234, 250, 252, 262, 264, which can be, but are not         limited to, pilot valves, cam operated poppet valves, rotary         valves, hydraulically or pneumatically actuated valves and         electronically actuated valves or any combination thereof;     -   hydroturbine generators 156, 251, or 902, which are used in         various embodiments for energy storage and generation system         100, as well as any other devices that can produce electricity         using the flow of a liquid, the different numbers being designed         to show a particaluar use for a particular system and the         possibility of a different device to produce electricity;     -   venting devices 158, 160, 162, 220, or 230, which can be used to         vent the vessels 110, 112, 114, 194,196, 253, 256, in which they         are fitted, to the atmosphere; with an electronically controlled         system, or an air valve, while having a primary function of         allowing proper displacement of air when pressure vessels 110,         112, 114, 194 or 196 are receiving liquid;     -   sensors 164, 166, 168, 170, 172, 174, 176, 178, 180, 214, 216,         218, 224, 226, or 228, which sense when the level of the liquid         in the vessels 110, 112, 114, 194, 196, 253, or 256 are at a         predetermined point and to communicate this information to the         device controlling the system processes which can be, but not         limited to a programmable controller, a host computer or         computers comprising a processor or processors in electronic         communication (local or remote) with one or more         computer-readable mediums, the computer storage mediums having         stored thereon one or more codes to instruct the processor to         receive signal from the various sensors in the system to monitor         the various parameters of the system and to control one or more         system elements in response to the parameters or in response to         other instructions from the codes;     -   pressure sensing devices 182, 184, 186, 210, and 212 record the         gas pressure within the vessels 110, 112, 114, 194, 196, 253, or         256, on which they are fitted, which is then communicated to the         device controlling the energy storage and generation system 100,         which can be, but is not limited to, a programmable controller,         a host computer or computers comprising a processor or         processors in electronic communication (local or remote) with         one or more computer or other readable mediums, the computer         storage mediums having stored thereon one or more codes to         instruct the processor to receive signal from the various         sensors in the system to monitor the various parameters of the         system and to control one or more system elements in response to         the parameters or in response to other instructions from the         codes;     -   pumps 190, 236, 254 transfer liquid from the reservoirs into any         of the vessels desired as described in the operations of energy         storage and generation system 100;     -   reservoirs 192 and 238 hold the liquids used in the energy         storage and generation system 100;     -   gas power generator 240, which is a device that can use         compressed air to generate electricity;     -   reaction generator 242, which is a device that can combine two         different gases chemically or otherwise and produce electricity         as a result of this combination;     -   gas receiver 244;     -   cryogenic container 246 with heat exchanging devices or coils         fitted in it or around its walls in such a way that it can         absorbs heat from the reservoir 248 to convert the cryogenic         fluids or solids to gas at high pressure, with the medium used         in the heat exchanging coils or devices being a gas or a liquid;     -   heat reservoir 248 containing ambient air, the ground, a large         body of water or any heat generating body, with the reservoir         248 must be at a reasonably higher temperature than the         cryogenic fluids or solids;     -   the hot liquid reservoir 258;     -   heat exchanger 260;     -   heat exchanger pump 266.

In FIG. 1, which demonstrates the prior art, water storage system 900 uses reversible turbine 902 to pump water 904 from lower container 906 to upper container 908. When desired, water 904 is released from upper container 908 to pass through reversible turbine 902, thereby generating electricity. Pumping from lower container 906 to upper container 908 occurs when there is low demand or an offpeak demand for electricity. With the water 904 in upper container 908, it may be released to pass through turbine 902 and generate electricity during periods of high demand. The great volume of water 904 required for this process is one of the main reasons this process is not efficient.

With FIG. 2, the function of the energy storage and generation system 100, has one embodiment as electrical integrating device 404, which integrates electrical power from the external electrical power source 102 and those generated by the hydroturbine generator 156 in such a way that all the power generated from the hydroturbine generator 156 is used in running the gas supply device 108 and any extra power needed for this purpose is then taken from the external power source 102. The electrical integrating device 404 is also used to supply power from the gas supply device 108 to an external load when the gas supply device 108 is running in reversible mode. The electrical integrating device 404 can be as simple as a set of diodes, transistors and switches or it can be a more sophisticated electronic device.

FIG. 3, FIG. 4, FIG. 5, FIG. 6, and FIG. 7 combine to show how a conventional pumped storage hydroelectricity device 900 can be combined with the simplified compressed air circuit 410 to show one version of energy storage system 100 to form a single system that will be more efficient than either of the two systems working independently. In FIG. 4, electrical power is fed to the reversible compressor 108 or expander and compressed air flows down the pipeline forcing the liquid in the lower reservoir 414 up into the upper reservoir 416. At the completion of the process, the lower reservoir 414 now contains compressed air while the upper reservoir 416 will contain the liquid or water 904 as shown in FIG. 5.

When the time comes to utilize the energy that is being stored in this way, the compressed air in the lower reservoir 414 is passed back through the pipeline 420 into the reversible compressor 108 or expander. The compressor 108 generates electricity in this process which is called generation stage 430 as shown in FIG. 6. When the compressed air is being depleted, the liquid in the upper reservoir 416 now runs down through the pipeline as shown in FIG. 7, the hydroturbine generator 156 generating electricity in the process. This is called the generation stage 2. All this systems are called open systems in that the output of the systems are not used as a feedback to the system.

FIGS. 8 through 25 cover the invention of this application, while FIGS. 1 through 7 depict the prior art. The compressed liquid and compressed gas use of FIGS. 8 through 25 are far more efficient than the arrangement of the prior art.

FIG. 8, FIG. 9, FIG. 10, and FIG. 11 combine to show an upgraded or improved system for energy storage system 100 that is a closed system 320, which means output from the closed system 320 is utilized in a feedback arrangement that will result in a dramatic improvement in the overall system efficiency. In FIG. 9, electrical power from an external source is fed through the integrating device 104 to the reversible compressor 108. The function of the integrating device 104 is to integrate electrical power from the external electrical power source 102 and that power generated by the hydroturbine generator 156, in such a way that all of the power generated from the hydroturbine generator 156 is used in running the compressor 108 and any extra power needed for this purpose is then taken from the external power source 102.

The compressed air generated flows through pipe 516 into the air receiver 508 and then into first vessel 520 which is filled with liquid. The pressure of the air forces the liquid through the hydroturbine into second vessel 522 as shown in FIG. 10. Electrical power is generated by the hydroturbine generator 156. Then this power is looped back or recycled through the integrating device 104 to assist in powering the expander or reversible compressor 108.

At the completion of the process, first vessel 520 now contains compressed air while vessel B (which before was empty) now contains liquid as shown in FIG. 10. When the energy stored is needed, the compressed air in vessel A is directed as shown by the solid arrows in FIG. 11 to the reversible compressor 108, generating electrical power (depicted by the dashed arrows) in the process.

Referring now to FIG. 12, the external power source 102 initially powers the compressor 108 which compresses the liquid in pressure vessel 253, the compressed liquid then goes through the hydroturbine generator 156 to the pressure vessel 256. In the process electricity is produced by the hydroturbine generator 156 and this is subsequently used to power the compressor 108 through the changover switch or integrating device 104 which cuts off power from the external power source at the same time. At a predetermined time when liquid in vessel is sufficiently low, pump 254 comes on to recycle some of the liquid in vessel 253 such that it flows to reservoir 258 after being sprayed in vessel 253 to capture heat from the compressed gas.

This process continues until vessel 253 is almost empty of liquid and filled at the same time with compressed gas, at which point the compressor 108 108 shuts off. Energy in the form of compressed gas is now available for use whenever needed from vessel 253. When demanded, the compressed gas flows out of vessel 253 through the heat exchanger 260 to the point of use. Alternatively the hot liquid in reservoir 258 can be sprayed directly into the compressed gas at the point of use as it is getting decompressed such that the expanding gas now extracts heat directly from the liquid.

Vessels 253 and 256 here can also be multiple vessels (as many as may be desired) arranged to perform the same functions. An example of multiple vessel system is presented in, but not limited to, the following descriptions:

Multiple Vessel System

The multiple vessel system can operate with as many pressure vessels as desired. The pressure vessels are not restricted to a linear arrangement as shown in the figures (which is only for simplicity) but can be in any configuration desired. A three vessel system 320 operation is described in FIG. 13, FIG. 14, FIG. 15, FIG. 16, FIG. 17, FIG. 18, FIG. 19 and FIG. 20.

In the system operation for three vessel system 320 for the generation mode 330, switch 116 is closed to begin the operation. Electrical power flows through the integrating device 104 into the system so that valve 188 opens and liquid is pumped from reservoir 192 by the pump 190 into one of the three vessels, which is assumed for this description to be vessel 110 until upper limit (in this case on sensor 176) is reached. The gas supply device 108, which in the case of a compressor 108 generates compressed gas into the receiving vessel 106. Valves 122 and 126 are closed during this process. This is called the powering up stage 332 (FIG. 1 3). This stage ends when gas supply device cuts off (such as when a compressor 108 cuts off at the predetermined pressure) and initializing stage 334 commences.

As the three vessel system 320 cycle progress comes on, if it is determined that there is a shortage of liquid to fill up any of the three vessels 110, 112, and 114 to the upper limits (as determined by sensors 176, 178, and 180 respectively) when this is required during the operation, the three vessel system 320 will pause the system cycle and instruct pump 190 to fill up the particular vessel of any of the three vessels 110, 112 and 114; which need filling. Then the system cycle will resume where it left off.

When the gas pressure in receiving vessel 106 reaches an upper predetermined pressure (for example compressor 108 cuts off) valve 122, valve 132, valve 136, valve 140 and valve 160 open while switch 120 closes. The pressurized gas from receiving vessel 106 forces the liquid from vessel 110 through the hydroturbine generator 156 into another vessel, for example, pressure vessel 112 for explanation purposes. The electrical energy generated by the hydroturbine generator 156 flows through switch 120 to the integrating device 104 and is looped back to power the gas supply device 108. This will reduce the power now being drawn from the external power source 102. This is called the initializing stage 334 (FIG. 14).

This process or initializing stage 334 continues until the liquid level in vessel 110 reaches a low limit determined by limit sensor 164 at which point valve 150 and venting device 162 opens, after which valve 140 and 160 closes while valve 140 and valve 144 opens. This has the effect of feeding the hydroturbine generator 156 from vessels 110 and 112 at the same time, while vessel 114 receives liquid coming from hydroturbine generator 156. Thus is first transition stage 336 (FIG. 1 5).

FIG. 15 and FIG. 16 combine to explain and coordinate first transition stage 336 and second cycle stage 338 respectively. This first transition stage 336 of FIG. 15 continues until the liquid in vessel 110 reaches a lower limit determined by limit sensor 166 at which point, valve 132 and valve 136 closes. This has the effect of feeding hydroturbine generator 156 from vessel 112 alone while vessel 110 contains compressed gas. The gas in vessel 110 can be used to power any suitable equipment or to generate electrical power as needed. This is called the second cycle stage 338 (FIG. 16).

The compressed gas in vessel 110 for first transition stage 336 and second cycle stage 338 can be used in two ways:

-   -   i. Valve 130 and valve 138 open allowing compressed gas to move         from vessel 110 to any external device that can be powered by         it. Valve 138 stays open for the rest of the energy storage         system 100 operation. This can be done while other processes in         the system continues to run. This is the more common way this         energy storage system 100 will be used and will be assumed in         the description of the system operation.     -   ii. A second option is that all other processes in the energy         storage system 100 is paused, wherein valve 126, valve 128 and         valve 130 open, thereby allowing the compressed gas to flow         through the reversible gas supply device 108 to generate         electricity which is fed to an external load through the         integrating device 104 and switch 118. It is also possible to         bypass the integrating device 104 in this case by use of diodes         and other electrical and electronic devices so that there is a         separate path to the external load if this is so desired.

In FIG. 17, the process of feeding the hydroturbine generator 156 from vessel 112 continues until the low limit determined by limit sensor 168 is reached. If by this time the compressed gas in vessel 110 is being depleted, then valve 130 closes while valves 134 and 158 opens (if the compressed gas contained in any of the vessels 110, 112 and 114 at any time during the system operation are not used up, the system will pause other operations while allowing the remaining gas in any of the vessels to be consumed after which system operation picks up where it left off). After this valve 150 and venting device 162 closes while valve 148 and valve 154 opens. This effectively feeds hydroturbine generator 156 from vessels 112 and 114, while liquid returns from the hydroturbine generator 156 to vessel 110, this is called transition stage 2 or second transition stage 350.

Referring now to FIG. 18, when lower limit 170 is reached in vessel 112, valve 140 and valve 142 closes so that hydroturbine generator 156 is now fed from vessel 114. Valve 146 opens to allow compressed gas in 112 to power any suitable external device or equipment, this is called third cycle stage 352.

Then turning to FIG. 19, this process continues until a limit determined by sensor 172 in vessel 114 is reached and if compressed gas in vessel 112 is depleted, then valve 140 and valve 160 open. After this valves 134 and 158 close while valve 132 and valve 136 open, effectively feeding hydroturbine generator 156 from vessels 110 and 114, while liquid returns from the hydroturbine generator 156 to vessel 112. This is called third transition stage 344.

In FIG. 19, when the lower limit determined by sensor 174 in vessel 114 is reached, valve 148 and valve 154 close. This set up implies that hydroturbine generator 156 is now being fed by vessel 110 alone.

In this fashion, FIG. 20 depicts how energy storage system 100 thus comes back to how things were at the initializing stage of the operation cycle, except that liquid has now passed through all three vessels. Vessel 114 now contains compressed gas which is subsequently released to power any suitable devices or equipment when valve 152 opens. This stage is, therefore called first cycle stage 348 to differentiate it from the initializing stage 334.

The energy storage system 100 then goes through the first cycle stage 348, first transition stage 336, second cycle stage 338, second transition stage 350, third cycle stage 352, third transition stage 354 and back to first cycle stage 348 repeatedly as long as the compressed gas in the vessels 110, 112 and 114 is being used up. If the gas is not used up the energy storage system 100 will pause until the gas is used up, after which the cycle resumes.

The energy storage system 100 processes can be controlled by devices or systems which can be, but are not limited to a programmable controller, an EPROM, a host computer or computers comprising processor or processors in electronic communication (local or remote) with one or more computer-readable mediums, the computer storage mediums having stored thereon one or more codes to instruct the processor to receive signal from the various sensors in the system to monitor the various parameters of the system and to control one or more system elements in response to the parameters or in response to other instructions from the codes.

Energy Storage Mode

The energy storage system 100 can also operate on storage mode. In this case energy is stored for later use in the form of, but not limited to, compressed gas. When operated in this mode, the energy storage system 100 can hibernate until the compressed gases are used up after which the operating cycle resumes.

As an example of operation in storage mode, the system after powering on and initializing will go into first transition stage 336 and second cycle stage 338 as described in the generation mode except that valve 130 and valve 138 will remain closed. This will have the effect of keeping compressed gas in vessel 110 instead of releasing it for use. After this the system hibernates until the gas in vessel 110 is used up after which it resumes the rest of the cycle of operation.

The energy storage system 100 can also go into the storage mode at any part of the operating cycle. Valves 130, 138, 146 and 152 will all remain closed and compressed gas will be held in any of the vessels 110, 112 and 114 that may be containing them at the point in the cycle when storage mode is activated and the system goes into hibernation. To resume valve 138 opens. Then any of valves 130, 146 and 152 which are controlling the particular vessel with unreleased gas (evidenced by the fact that level of liquid in that particular vessel is at or below limit sensor 164 for vessel 110, limit sensor 168 for vessel 112, limit sensor 172 for vessel 114 will open and compressed gas contained therein will be used as desired and the system will pick up where it left off on the operating cycle.

Three Vessels Operation Sequence

At the start of the first cycle 330 (powering on) as shown in FIG. 13, this stage ends when gas supply device cuts off (typically such as when compressor 108 cuts off at the predetermined pressure) and the start of initializing second cycle stage 338 (FIG. 14) then commences.

Status of System Elements—at Start of First Cycle 330 (FIG. 3)

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 OPEN valve 122 CLOSED valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 CLOSED valve 132 CLOSED valve 134 CLOSED valve 136 OPEN valve 138 CLOSED valve 140 CLOSED valve 140 CLOSED valve 144 CLOSED valve 146 CLOSED valve 148 CLOSED valve 150 CLOSED valve 152 CLOSED valve 154 CLOSED hydroturbine generator 156 NOT GENERATING POWER venting device 158 OPEN venting device 160 CLOSED venting device 162 CLOSED valve 188 OPEN

Start of Cycle 2 or Second Cycle Stage 338-Initializing (FIG. 14)

This stage ends when low point as indicated by limit sensor 164 is reached on vessel 110. First transition stage 336 then starts.

Status of System Elements at/start of Second Cycle Stage 338

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 CLOSED valve 122 OPEN valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 CLOSED valve 132 OPEN valve 134 CLOSED valve 136 OPEN valve 138 CLOSED valve 140 OPEN valve 140 CLOSED valve 144 CLOSED valve 146 CLOSED valve 148 CLOSED valve 150 CLOSED valve 152 CLOSED valve 154 CLOSED hydroturbine generator 156 GENERATING POWER venting device 158 CLOSED venting device 160 OPEN venting device 162 CLOSED valve 188 CLOSED

First Transition Stage FIG. 15

This stage ends when lower point 166 is reached in vessel 110. Second Cycle stage 338 then starts.

Status of System Elements During First Transition Stage 336 FIG. 15

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 CLOSED valve 122 OPEN valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 CLOSED valve 132 OPEN valve 134 CLOSED valve 136 OPEN valve 138 OPEN valve 140 CLOSED valve 140 OPEN valve 144 OPEN valve 146 CLOSED valve 148 CLOSED valve 150 OPEN valve 152 CLOSED valve 154 CLOSED Hydroturbine 156 GENERATING POWER venting device 158 CLOSED valve 160 CLOSED venting device 162 OPEN valve 188 CLOSED

Cycle Stage 2 or Second Cycle Stage 338

This stage ends when low point 168 is reached in vessel 112. Transition stage 2 or second transition stage 350 then starts.

Status of System Elements During Cycle Stage 2 or Second Cycle Stage 338

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 CLOSED valve 122 OPEN valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 OPEN valve 132 CLOSED valve 134 CLOSED valve 136 CLOSED valve 138 OPEN valve 140 CLOSED valve 140 OPEN valve 144 OPEN valve 146 CLOSED valve 148 CLOSED valve 150 OPEN valve 152 CLOSED valve 154 CLOSED hydroturbine generator 156 GENERATING POWER venting device 158 CLOSED venting device 160 CLOSED venting device 162 OPEN valve 188 CLOSED

Transition Stage 2 or Second Transition Stage 350

This stage ends when lower point 170 is reached in vessel 112. Cycle stage 3 or third cycle stage 352 then starts.

Status of System Elements During Transition Stage 2 or Second Transition Stage 350

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 CLOSED valve 122 OPEN valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 CLOSED valve 132 CLOSED valve 134 OPEN valve 136 CLOSED valve 138 OPEN valve 140 CLOSED valve 140 OPEN valve 144 OPEN valve 146 CLOSED valve 148 OPEN valve 150 CLOSED valve 152 CLOSED valve 154 OPEN hydroturbine generator 156 GENERATING POWER venting device 158 OPEN venting device 160 CLOSED venting device 162 CLOSED valve 188 CLOSED

Cycle Stage 3 or Third Cycle Stage 352

This stage ends when low point 172 is reached in vessel 114. Transition stage 3 then starts.

Status of System Elements During Cycle Stage 3 or Third Cycle Stage 352

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 CLOSED valve 122 OPEN valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 CLOSED valve 132 CLOSED valve 134 OPEN valve 136 CLOSED valve 138 OPEN valve 140 CLOSED valve 140 CLOSED valve 144 CLOSED valve 146 OPEN valve 148 OPEN valve 150 CLOSED valve 152 CLOSED valve 154 OPEN hydroturbine generator 156 GENERATING POWER venting device 158 OPEN venting device 160 CLOSED venting device 162 CLOSED valve 188 CLOSED

Third Transition Stage 344

This stage ends when lower point 174 is reached on vessel 114. Cycle stage 1 or first cycle stage 348 or first cycle stage 348 then starts.

Status of System Elements/during Third Transition Stage 344

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 CLOSED valve 122 OPEN valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 CLOSED valve 132 OPEN valve 134 CLOSED valve 136 OPEN valve 138 OPEN valve 140 OPEN valve 140 CLOSED valve 144 CLOSED valve 146 CLOSED valve 148 OPEN valve 150 CLOSED valve 152 CLOSED valve 154 OPEN hydroturbine generator 156 GENERATING POWER venting device 158 CLOSED venting device 160 OPEN venting device 162 CLOSED valve 188 CLOSED

Cycle Stage 1 or First Cycle Stage 348

First cycle stage 348 ends when low point as indicated by limit sensor 164 is reached in vessel 110. The system then reverts to transition stage 1 or first transition stage 336. This completes the system cycle as the system will now run repeatedly through the following stages; cycle stage 1 or first cycle stage 348 or first cycle stage 348, transition stage 1 or first transition stage 336, cycle stage 2 or second cycle stage 338, transition stage 2 or second transition stage 350, cycle stage 3 or third cycle stage 352 and transition stage 3. This situation will continue unless the system is stopped or instructed to revert to another program.

Status of System Elements During Cycle Stage 1 or First Cycle Stage 348

electrical switch 116 CLOSED electrical switch 118 OPEN electrical switch 120 CLOSED valve 122 OPEN valve 124 OPEN valve 126 CLOSED valve 128 CLOSED valve 130 CLOSED valve 132 OPEN valve 134 CLOSED valve 136 OPEN valve 138 OPEN valve 140 OPEN valve 140 CLOSED valve 144 CLOSED valve 146 CLOSED valve 148 CLOSED valve 150 CLOSED valve 152 OPEN valve 154 CLOSED hydroturbine generator 156 GENERATING POWER venting device 158 CLOSED venting device 160 OPEN venting device 162 CLOSED valve 188 CLOSED

FIVE VESSEL OPERATION EXAMPLE

FIG. 21 depicts a five vessel closed system 600 of the invention. More details are given in the written description and Table 1.

An example of a five vessel system is presented but not limited to the following descriptions in FIG. 21 and the tables. When the system is turned on it will go through the powering up, initializing, transition stage 1 or first transition stage 336, cycle stage 2 or second cycle stage 338, transition stage 2, cycle stage 3, transition stage 3, cycle stage 4, transition stage 4 or fourth transition stage 356, cycle stage 5, transition stage 5, cycle stage 1 and transition stage 1 or first transition stage 336 respectively. After this the system will settle down to cycling repeatedly through the following series: transition stage 1 or first transition stage 336, transition stage 2, cycle stage3, transition stage3, cycle stage 4, transition stage 4 or fourth transition stage 356, cycle stage 5, transition stage 5, cycle stage 1 and back to transition stage 1 or first transition stage 336.

FIG. 23 depicts a multi-liquid system 700 in operation. It is focused on one of the vessels (vessel 110) in the system and also highlighted the use of addition pump 236, valve 234 and reservoir 238 to inject the second fluid into the system. Additional pumps, valves and reservoirs can be added as may be desired depending on how many liquids are used. FIG. 24 depicts how the invention will work when the gas supply device 108 is electrolytic.

Some Other Embodiments of the Invention

There are other instances when the system must be configured to adapt to various situations such as when the gas supply device may be some other devices other than a compressor 108 or when dealing with high pressures. Below are some of such embodiments like the cryogenic, electrolytic, multifluid and open systems.

Cryogenic Systems

FIG. 25 shows a three vessel cryogenic system. In this case the gas supply device 108 is a cryogenic cooling system to produce liquified (or in some cases solidified) gases. In the case of the cryogenic cooling system, the gas receiver is simply replaced by an apparatus that will store liquefied or solidified gases as well as the means to convert them back to gas under pressure. An example of such an apparatus is shown in FIG. 25, in this case the cryogenic liquid or solid produced by the cryogenic cooling system 108 is stored inside a cryogenic container 246.

Valve 250 opens to allow the cryogenic fluids to pass and closes after container 246 is being filled to the desired capacity. In the case of a solidified gas, there will be the need to have a means of propelling the cryogenic materials into the container 246. Such means can be but are not limited to a set of screw conveyors installed in the pipeline.

When compressed gas is needed the cryogenic fluid absorbs the necessary heat of vaporization from the heat reservoir 248 through the heat exchanging coils in container 246. Another alternative will be to wrap the coils of the heat exchanger around the container 246, pump 266 drives the medium used inside the heat exchanging coils. Such mediums can be liquid or gas depending on the nature of the heat reservoir 248.

Electrolytic Systems

In the case of the electrolytic system (FIG. 24), gas is produced by the passage of electricity through a suitable electrolyte in the gas supply device 108. The gas is then kept under pressure in a suitable receiving vessel 106 and used as had been previously described. The only difference is that electrolytic processes can produce more than one gaseous product. Each gas is used separately to power its own system as shown in FIG. 24. The figure is showing the case when there are two gaseous products from the electrolytic process but equally applies when there are more.

An interesting aspect of this embodiment is that power can be recovered back from the gases released in the system in more than one way. Firstly power can be tapped from the pressure of the gases through the pressure equipment 240 which are designed to use gas pressure to operate. The pressure equipment can give out electricity as the output as shown in the figure or some other type of output such as mechanical work or any other desired output can be obtained.

Secondly power can be obtained from the chemical energy of the gases through the chemical equipment 242 which is designed to give out electricity or any other desired output from the chemical energy and processes of the gaseous output from the system, for example recombining the gases as in a fuel cell or any other desired way of utilizing the chemical energy of the gases. Sometimes the gases themselves might be the desired end product to be shipped or distributed to customers, in which case they are then stored in appropriate containers. It may be noted that the outputs (electricity, mechanical work e.t.c) from the multiple gas systems are shown as separate in FIG. 24 below but in practice they can also be combined to form one single output.

Multiple Liquids or Diaphragms

The system can also use multiple liquids (multi-fluid) where two or more different liquids are used in the pressure vessels. A system with two working liquids is shown in FIG. 23. Here, focus is on one of the vessels in a three or five vessel system (vessel 110) to explain how this works. Liquid 2 can serve as a buffer or barrier or seal for liquid 1 in cases where liquid 1 will be affected by the gas used for example high pressure applications or possibility of chemical reactions. In this case liquid 2 will be more resistant to the conditions of the gases. Valve 224 controls the flow of liquid 2 which is pumped by pump 236 from the liquid reservoir 238. The system 100 operates in much the same way as had been described before for a three or five vessel system with the exception that multiple liquids are used. It is also possible to use other means including but not limited to diaphragms or other types of barriers to separate the gas from the liquids.

Open System

What is most unique to this invention and sets it apart from other prior art is what is referred to as an energy loop whereby the output from the hydroturbine generator 156 is fed back to the gas generating devices to boost system efficiency. However, the system can also be open in which case the output from the hydroturbine is used in some other way and the system is sustained by the external electrical power source and still releases compressed air at the intervals described in the operating cycle for use. This is shown in FIG. 22.

FIG. 26 shows the three vessel system 320 with a heat capture function. The heat capture function is accomplished by having vessel 292 filled with a heat absorbing medium (such as liquid water or any other suitable medium) and containing heat exchanging coils 322 to facilitate heat transfer. Alternately, the compressed gas may be bubbled through the medium. The heat thus captured can be transferred back to the gas released through valve 138 before it is used up.

In the following examples, which are intended to illustrate without unduly limiting the scope of this invention, all parts and percentages are by unless otherwise indicated.

Example 1

In FIG. 1, FIG. 2, FIG. 3, FIG. 4, FIG. 5, FIG. 6, and FIG. 7, which demonstrate the prior art, water storage system 900 uses reversible turbine 902 to pump water 904 from lower container 906 to upper container 908. When desired, water 904 is released from upper container 908 to pass through reversible turbine 902, thereby generating electricity. Pumping from lower container 906 to upper container 908 occurs when there is low demand for electricity. With the water 904 in upper container 908, it may be released to pass through turbine 902 and generate electricity during periods of high demand. There are more units of electricity required to pump water 904 from lower container 906 to upper container 908 than are produced when water flows from upper container 908 through reversible turbine 902 into lower container 906. The only advantage is that electricity is available during periods of high demand.

Example 2

A three vessel system 320 operation is described in FIG. 13, FIG. 14, FIG. 15, FIG. 16, FIG. 17, FIG. 18, FIG. 19 and FIG. 20.

In the system operation for three vessel system 320 for the generation mode 330, switch 116 is closed to begin the operation. Electrical power flows through the integrating device 104 into the system so that valve 188 opens and liquid is pumped from reservoir 192 by the pump 190 into one of the three vessels, which is assumed for this description to be vessel 110 until upper limit (in this case on sensor 176) is reached. The gas supply device 108, which in the case of a compressor 108 generates compressed gas into the receiving vessel 106. Valves 122 and 126 are closed during this process. This is called the powering up stage 332 (FIG. 1 3). This stage ends when gas supply device cuts off (such as when a compressor 108 cuts off at the predetermined pressure) and the start of cycle 2 or second cycle stage 338—initializing stage 334 then commences.

As the three vessel system 320 cycle progress comes on, if it is determined that there is a shortage of liquid to fill up any of the three vessels 110, 112, and 114 to the upper limits (as determined by sensors 176, 178, and 180 respectively) when this is required during the operation, the three vessel system 320 will pause the system cycle and instruct pump 190 to fill up the particular vessel of any of the three vessels 110, 112 and 114; which need filling. Then the system cycle will resume where it left off.

While the foregoing describes some ways the invention can be used on its own or in combination with some other systems, it may be pointed out that there will be the existence of variations, combinations and equivalents of the specific embodiments, methods, and examples herein or combinations with some other energy storage systems. The invention may, therefore, not be limited by the above described embodiments, methods and examples, but by all embodiments and methods within the scope and spirit of the invention.

This application—taken as a whole with the abstract, specification, claims, and drawings being combined—provides sufficient information for a person having ordinary skill in the art to practice the invention as disclosed and claimed herein. Any measures necessary to practice this invention are well within the skill of a person having ordinary skill in this art after that person has made a careful study of this disclosure.

Because of this disclosure and solely because of this disclosure, modification of this method and device can become clear to a person having ordinary skill in this particular art. Such modifications are clearly covered by this disclosure. 

What is claimed and sought to be protected by Letters Patent of the United States is:
 1. An energy storage and generation system for storing or producing electricity comprising: a compressed gas system being used to provide electricity; a liquid system cooperating with the compressed gas system to provide electricity; the compressed gas system and the liquid system storing an energy producing capability at a time when electricity requirements are low; the compressed gas system and the liquid system releasing the energy producing capability at a time when electricity requirements are high; at least one compressed gas vessel receiving or releasing gas; at least two liquid vessels receiving or releasing liquid; the at least one compressed gas vessel and the at least two liquid vessels communicating to assist in production or storage of electricity; at least one liquid valve controlling passage of a liquid for the at least two liquid vessels; and at least one gas valve controlling passage for the at least one gas vessel.
 2. The energy storage and generation system of claim 1 further comprising: the at least one compressed gas vessel and the at least two liquid vessels cooperating with a hydroturbine generator in order to produce or store electricity as required; an energy loop feeding an electrical output from the hydroturbine generator back to a gas generating device to boost efficiency for the energy storage and generation system; the at least one compressed gas vessel receiving the gas from or releasing the gas to a compressor; the at least two liquid vessels receiving the liquid from or releasing the liquid to the hydroturbine generator; the at least one gas valve controlling the gas in a gas vessel; the at least one liquid valve controlling the liquid in a liquid vessel; and at least one sensor testing either an amount of the gas in the at least one gas vessel or an amount of the liquid in the at least two liquid vessels.
 3. The energy storage and generation system of claim 2 further comprising: the at least one sensor providing an appropriate adjustment for the amount of the gas or the amount of the liquid; an electrical integrating device cooperating with an external electrical power source; the electrical integrating device or the external electrical power source cooperating with a hydroturbine generator; the hydroturbine generator providing at least partial power to operate a gas supply device; the external electrical power source compensating for a deficit in power for the gas supply device; and the gas and the liquid cooperating to have the hydroturbine generator produce a quantity of electricity on high demand and a storage of electricity at low demand.
 4. The energy storage and generation system of claim 3 further comprising: at least two upper reservoirs and at least one lower reservoir serving as the at least one compressed gas vessel or the at least two liquid vessels; the at least two upper reservoirs serving as a storage vessel when containing liquid; the at least two upper reservoirs receiving compressed gas from the at least one compressed gas vessel in order to release or expel liquid therefrom to pass through the hydroturbine generator to generate power; a reversible compressor causing a storage of energy as the compressed gas forces the liquid from the at least one lower reservoir into the at least two upper reservoirs, so that the at least one lower reservoir now contains the compressed gas while the at least two upper reservoirs contain the liquid; and the reversible compressor causing an output of energy in excess of an input of energy to cause storage of energy as the compressed gas forces the liquid from the at least two upper reservoirs into the at least one lower reservoir.
 5. The energy storage and generation system of claim 4 further comprising: a closed system forming a part of the energy storage and generating system; the closed system providing an energy output to the energy storage system; part of an energy output from the closed system providing a feedback arrangement for improvement in efficiency; electrical power from an external source being fed through the electrical integrating device to a reversible compressor; the reversible compressor integrating the electrical power from the external source and hydroturbine generator; electric power generated from the hydroturbine generator running the reversible compressor; support power for the reversible compressor coming from the external source; if required; the compressed air flowing sequentially through a pipe, into an air receiver, into a first vessel which is filled with a liquid; and the liquid passing through the hydroturbine generator to generate electricity.
 6. The energy storage and generation system of claim 5 further comprising: the hydroturbine generator producing power to be recycled through the integrating device and to assist in powering the reversible compressor; the electrical integrating device being a set of diodes, at least one transistor, at least one switch, or an electronic device; the external power source initially powering the reversible compressor; the the reversible compressor compressing the liquid to form a compressed liquid; a series of pressure vessels having a configuration for the system; the at least two liquid vessels receiving the liquid from or releasing the liquid to the hydroturbine generator; at least one valve controlling the gas in the at least one gas vessel or the liquid in the at least two liquid vessels; and the at least one gas vessel being a pressure vessel.
 7. The energy storage and generation system of claim 6 further comprising: the pressure vessel being used in a pressure series; the pressure vessel numbering at least two pressure vessels in the pressure series; and the at least one gas valve and the at least one liquid valve having a control system and a monitoring system.
 8. The energy storage and generation system of claim 7 further comprising: the at least two liquid vessels being three or five in number; the at least one gas valve and the at least one liquid valve having a computer as the control system; the at least one gas valve and the at least one liquid valve having a control system and a monitoring system; the monitoring system including the at one sensor; and the at least two liquid vessels of three or five in number having a linear arrangement.
 9. A method for storing or producing electricity comprising: using a combination of a compressed gas system and a liquid system to provide an energy storage and generation system in order to store or produce electrical energy as desired; providing the combination with a storage function at a time when electricity requirements are low; providing the combination with a electrical production function at a time when electricity requirements are high; providing at least one compressed gas vessel for the compressed gas system to receive or release gas as required; providing at least at least two liquid vessels for the liquid system to receive or release liquid as required; and the at least one compressed gas vessel and the at least at least two liquid vessels communicating to assist in production or storage of electricity.
 10. The method of claim 9 further comprising: providing at least one liquid valve to control passage of the liquid for the at least at least two liquid vessels; providing at least one gas valve to control passage of the gas for the at least one gas vessel; providing a hydroturbine generator to cooperate with the at least one gas vessel and the at least one liquid vessel in order to produce or store electricity as required; having the at least one gas vessel receive the gas from or release the gas to a compressor; having the at least at least two liquid vessels receive the liquid from or release the liquid to the hydroturbine generator; controlling the gas in a gas vessel with the at least one gas valve; controlling the liquid in the at least two liquid vessels with the at least one liquid valve; and testing either an amount of the gas in the at least one gas vessel or an amount of the liquid in the at least one liquid vessel with at least one sensor.
 11. The method of claim 10 further comprising: providing an appropriate adjustment for the amount of the gas or the amount of the liquid with at least one sensor; forming the energy storage and generation system with an electrical integrating device in cooperation with an external electrical power source; adapting the energy storage and generation system to provide cooperation between a hydroturbine generator and the electrical integrating device or the external electrical power source cooperating; operating a gas supply device at least partially with the hydroturbine generator; compensating power for gas supply device with the external electrical power source; producing a quantity of electricity on high demand and a storage of electricity at low demand with the gas and the liquid operating the hydroturbine generator; and providing at least one upper reservoir and at least one lower reservoir to serve as the at least one compressed gas vessel or the at least one liquid vessel.
 12. The method of claim 11 further comprising: having the at least one upper vessel serve as a storage vessel when containing liquid; providing compressed gas from the at least one compressed gas vessel to the at least one upper vessel in order to release or expel liquid therefrom to pass through the hydroturbine generator in order to generate power; storing energy with a reversible compressor a storage of energy as the compressed gas forces the liquid from the at least one lower reservoir into the at least one upper reservoir, so that the at least one lower reservoir now contains the compressed gas while the at least one upper reservoir contains the liquid; providing the reversible compressor with an output of energy in excess of an input of energy to cause storage of energy as the compressed gas forces the liquid from the at least one upper reservoir into the at least one lower reservoir; and providing the energy storage and generation system as a three vessel system.
 13. The method of claim 12 further comprising: flowing electrical power through the electrical integrating device into a system valve to open the valve; pumping a liquid from a lower vessel to a higher vessel; filling the lower vessel with a gas; providing the lower with a compressed from the gas; monitoring a level of the liquid in the higher vessel; using a sensor to monitor the level of the liquid in the higher vessel; using the sensor to stop a flow of the liquid into the higher vessel when a desired level is reached; providing an energy loop to feed an electrical output from the hydroturbine generator back to a gas generating device to boost efficiency for the energy storage and generation system; releasing the liquid from the higher vessel through a pipe; providing communication between the pipe and a hydroturbine generator; flowing the liquid from the pipe through the hydroturbine generator in order to produce electricity when desired.
 14. The method of claim 13 further comprising: providing the compressed gas with the reversible compressor; controlling the flow of the liquid with at least a first valve; controlling the flow of the gas with at least a second valve; monitoring the flow of the liquid and the flow of the gas; controlling the at least a first valve and the least a second valve in order to stop or start the liquid or the flow of the gas as required; increasing an electrical output relative to the electrical input due to cooperation between the flow of the liquid and the flow of the gas; pumping the liquid from a lower vessel to an upper vessel at an offpeak time of power requirement; and releasing the liquid from the upper vessel to the hydroturbine generator with pressure from the gas, a combined force of the gas and the liquid providing a substantial powewr advantage.
 15. The method of claim 14 further comprising: providing a three vessel system for a cycle system; controlling a fluid level in each vessel in the three vessel system; stopping the cycle system if the liquid level of any vessel in the three vessel system is insufficient to fill up the three vessel system; filling each vessel in the three vessel system sufficiently if required; providing the at least one sensor to check the filling of each vessel in the three vessel system; resuming the cycle system; providing a desired gas pressure to a receiving vessel to form pressurized gas; forcing the liquid from one or more vessels in the three vessel system through the hydroturbine generator at a desired pressure; receiving the liquid from hydroturbine generator into a pressure vessel; flowing electrical energy from the hydro turbine generator through a switch to an integrating device; and looping the electrical energy back to power the gas supply device.
 16. The method of claim 15 further comprising: reducing the power drawn from an external power source to provide an initializing stage; continuing the initializing stage the liquid level in the vessel reaches a low limit as determined by a limit sensor; adjusting at least one valve and at least one vent to adjust a feed for the hydroturbine generator; completing the first transition stage to lead to the second cycle stage; passing a compressed liquid through the hydroturbine generator to produce compressor power; spraying at least some of the liquid through a compressed gas chamber to capture some of the heat from the compressed gas; controlling power from the external power source; determining when the liquid level is low; activating a pump in order to recycle some of the liquid; and coordinating the pump with the sprayed liquid in order to capture heat from the compressed gas.
 17. The method of claim 16 further comprising: filling a vessel which is being empty of liquid with compressed gas; using the compressed gas; spraying hot liquid into the compressed gas so that the compressed gas can extract heat from the hot liquid; continuing an extraction until a vessel is almost empty of liquid and filled at the same time with compressed gas shutting down the compressor leaving compressed gas available for use as desired; flowing the compressed gas a heat exchanger to a point of use; allowing the compressed gas to flow through the reversible gas supply device to generate a second electricity source; feeding the second electricity source to an external load through an electronic device; feeding the hydroturbine generator from the vessel continues until the low limit is reached; and controlling the compressed gas.
 18. The method of claim 17 further comprising: providing a five vessel closed system; taking the five vessel closed system through a first transition stage for a powering up or initializing stage; leading from the first transition stage to a second cycle stage; leading from the second cycle stage to a second transition stage; leading from the second transition stage to a third cycle stage; leading from the third cycle stage to a third transition stage; leading from the third transition stage to a fourth cycle stage; leading from the fourth cycle stage to a fifth transition stage; leading from the fifth transition stage to a fifth cycle stage; and repeating the first transition stage to a fifth cycle stage as desired.
 19. The method of claim 18 further comprising including a cryogenic system or an electrolytic system.
 20. An energy storage and generation system for storing or producing electricity comprising: a compressed gas system being used to provide electricity with the energy storage and generation system; a liquid system cooperating with the compressed gas system to provide with the electricity energy storage and generation system; the compressed gas system and the liquid system storing an energy producing capability at a time when electricity requirements are low; the compressed gas system and the liquid system releasing the energy producing capability at a time when electricity requirements are high; at least one compressed gas vessel receiving or releasing gas; at least two liquid vessels receiving or releasing liquid; the at least one compressed gas vessel and the at least two liquid vessels communicating to assist in production or storage of electricity; at least one liquid valve controlling passage of a liquid for the at least two liquid vessels; at least one gas valve controlling passage for the at least one gas vessel; the at least one compressed gas vessel and the at least two liquid vessels cooperating with a hydroturbine generator in order to produce or store electricity as required; an energy loop feeding an electrical output from the hydroturbine generator back to a gas generating device to boost efficiency for the energy storage and generation system; the at least one compressed gas vessel receiving the gas from or releasing the gas to a compressor; the at least two liquid vessels receiving the liquid from or releasing the liquid to the hydroturbine generator; the at least one gas valve controlling the gas in a gas vessel; the at least one liquid valve controlling the liquid in a liquid vessel; at least one sensor testing either an amount of the gas in the at least one gas vessel or an amount of the liquid in the at least two liquid vessels; the at least one sensor providing an appropriate adjustment for the amount of the gas or the amount of the liquid; an electrical integrating device cooperating with an external electrical power source; the electrical integrating device or the external electrical power source cooperating with a hydroturbine generator to improve efficiency of production for electricity; the hydroturbine generator providing at least partial power to operate a gas supply device; the external electrical power source compensating for a deficit in power for the gas supply device; the gas and the liquid cooperating to have the hydroturbine generator produce a quantity of electricity on high demand and a storage of electricity at low demand; at least two upper reservoirs and at least one lower reservoir serving as the at least one compressed gas vessel or the at least two liquid vessels; the at least two upper reservoirs serving as a storage vessel when containing liquid; the at least two upper reservoirs receiving compressed gas from the at least one compressed gas vessel in order to release or expel liquid therefrom to pass through the hydroturbine generator to generate power; a reversible compressor causing a storage of energy as the compressed gas forces the liquid from the at least one lower reservoir into the at least two upper reservoirs, so that the at least one lower reservoir now contains the compressed gas while the at least two upper reservoirs contain the liquid; the reversible compressor causing an output of energy in excess of an input of energy to cause storage of energy as the compressed gas forces the liquid from the at least two upper reservoirs into the at least one lower reservoir; a closed system forming a part of the energy storage and generating system; the closed system providing an energy output to the energy storage system; part of an energy output from the closed system providing a feedback arrangement for improvement in efficiency; electrical power from an external source being fed through the electrical integrating device to a reversible compressor; the reversible compressor integrating the electrical power from the external source and hydroturbine generator; electric power generated from the hydroturbine generator running the reversible compressor; support power for the reversible compressor coming from the external source; if required; the compressed air flowing sequentially through a pipe, into an air receiver, into a first vessel which is filled with a liquid; the liquid passing through the hydroturbine generator to generate electricity; the hydroturbine generator producing power to be recycled through the integrating device and to assist in powering the reversible compressor; the electrical integrating device being a set of diodes, at least one transistor, at least one switch, or an electronic device; the external power source initially powering the reversible compressor; the reversible compressor compressing the liquid to form a compressed liquid; a series of pressure vessels having a configuration for the system; the at least two liquid vessels receiving the liquid from or releasing the liquid to the hydroturbine generator; at least one valve controlling the gas in the at least one gas vessel or the liquid in the at least two liquid vessels; and the at least one gas vessel being a pressure vessel. 